Method for determining the angular position of an electronic module fixed to the inner face of the tread of a tire

The invention claimed is: 1. A method for determining, during rotation of a wheel ( 2 ) of a vehicle ( 1 ) fitted with a tire ( 4 ), an angular position of an electronic module ( 5 ) fixed to an inner face of the tread ( 4 a ) of said tire, comprising: integrating a sensor ( 12 ) that measures a radial acceleration of the wheel ( 2 ) into the electronic module ( 5 ); making, by way of the sensor, at least one measurement of the radial acceleration, and using a value based on the at least one measurement to determine a value of a period (T) of revolution of the wheel ( 2 ); after the determining of the period (T) of revolution of the wheel ( 2 ), determining a sampling period by dividing the period (T) of revolution of the wheel ( 2 ) by a predetermined sampling rate (x), performing a plurality of measurements of the radial acceleration of the wheel ( 2 ) according to the determined sampling period, and detecting a variation of the plurality of measurements, the variation representative of a position of the electronic module ( 5 ) when a portion of the tire ( 4 ), upon which the electronic module ( 5 ) is affixed, is being in contact with the ground; determining the position of the electronic module ( 5 ) to be a location on the tire in which the variation of the radial acceleration is detected, and defining an origin sector (So) in terms of the determined position of the electronic module ( 5 ) on the tire when the tire is in contact with the ground and a reference unit of the tire formed by an angular unit sector (Su), the angular unit sector (Su) having a length that is shorter than a mean length of a footprint (Lfp) of the tire ( 4 ) on the ground, the footprint determined as a length between a falling edge and rising edge of the tire, the falling edge and rising edge determined by the variation of the radial acceleration detected from the electronic module ( 5 ) taking place when the portion of the tire upon which the electronic module ( 5 ) is affixed is in direct contact with the ground; and determining angular positions of the electronic module ( 5 ) inside a frame of reference defined by the origin sector (So), wherein the length of the origin sector (S o ) is the same length as the angular unit sector (S u ), and the length of the angular unit sector (S u ) is equal to the length rotated by the wheel ( 2 ) during the sampling period. 2. The method according to claim 1 , wherein the predetermined sampling rate (x) is equal to 20. 3. The method according to claim 2 , wherein the frame of reference is used for the determination of the angular positions of the electronic module ( 5 ), in which the transmission of signals between said electronic module and a central unit ( 14 ) on board the vehicle ( 1 ) is commanded. 4. The method according to claim 2 , wherein, the making at least one measurement of the radial acceleration by the sensor ( 12 ) and determining the period (T) of revolution of the wheel ( 2 ) comprises the sub-steps of, making at least three successive measurements of the radial acceleration, comparing the at least three successive measurements and discarding any of the at least three successive measurements which is smaller than any other of the at least three successive measurements and discarding by at least a predetermined threshold value, calculating a mean value of all non-discarded ones of the at least three successive measurements, and using said mean value to determine the value of the period (T) of revolution of the wheel ( 2 ). 5. The method according to claim 1 , wherein the frame of reference is used for the determination of the angular positions of the electronic module ( 5 ), in which the transmission of signals between said electronic module and a central unit ( 14 ) on board the vehicle ( 1 ) is commanded. 6. The method according to claim 5 , wherein, the making at least one measurement of the radial acceleration by the sensor ( 12 ) and determining the period (T) of revolution of the wheel ( 2 ) comprises the sub-steps of, making at least three successive measurements of the radial acceleration, comparing the at least three successive measurements and discarding any of the at least three successive measurements which is smaller than any other of the at least three successive measurements and discarding by at least a predetermined threshold value, calculating a mean value of all non-discarded ones of the at least three successive measurements, and using said mean value to determine the value of the period (T) of revolution of the wheel ( 2 ). 7. The method according to claim 1 , wherein, the making at least one measurement of the radial acceleration by the sensor ( 12 ) and determining the period (T) of revolution of the wheel ( 2 ) comprises the sub-steps of, making at least three successive measurements of the radial acceleration, comparing the at least three successive measurements and discarding any of the at least three successive measurements which is smaller than any other of the at least three successive measurements and discarding by at least a predetermined threshold value, calculating a mean value of all non-discarded ones of the at least three successive measurements, and using said mean value to determine the value of the period (T) of revolution of the wheel ( 2 ). 8. The method according to claim 7 , wherein the value of the period (T) of revolution of the wheel ( 2 ) is determined on the basis of values of radial acceleration measured at time intervals which are substantially equal to 30 milliseconds. 9. A method for determining, during rotation of a wheel ( 2 ) of a vehicle ( 1 ) fitted with a tire ( 4 ), an angular position of an electronic module ( 5 ), including a radial acceleration sensor ( 12 ) that measures a radial acceleration of the wheel ( 2 ), fixed to an inner face of the tread ( 4 a ) of the tire, comprising: making, by way of the radial acceleration sensor, three or more measurements of the radial acceleration, calculating a mean value of the three or more measurements, and using the calculated mean value of the three or more measurements to determine a value of a period (T) of revolution of the wheel ( 2 ); after the determining of the period (T), determining a sampling period by dividing the period (T) of revolution of the wheel ( 2 ) by a predetermined sampling rate (x), performing a plurality of measurements of the radial acceleration of the wheel ( 2 ) according to the sampling period, and detecting a variation of the plurality of measurements, the variation representative of a position of the electronic module ( 5 ) when a portion of the tire ( 4 ), upon which the electronic module ( 5 ) is affixed, is in contact with the ground; determining the position of the electronic module ( 5 ) to be a location on the tire in which the variation of the radial acceleration is detected, and defining an origin sector (So) in terms of the determined position of the electronic module ( 5 ) on the tire when in contact with the ground and a reference unit of the tire formed by an angular unit sector (Su), the angular unit sector (Su) having a length that is shorter than a mean length of a footprint (Lfp) of the tire ( 4 ) on the ground determined as a length between a falling edge and rising edge of the tire, the falling edge and rising edge determined by the variation of the radial acceleration detected from the electronic module ( 5 ); and determining angular positions of the electronic module ( 5 ) inside a frame of reference defined by the origin sector (So), wherein the length of the origin sector (S o ) is the same length as the angular unit sector (S u ), and the length of the angular unit sector (S u ) is equal to the length rotated by the wheel ( 2 ) during the